Distribution of glutamine synthetase and an inverse relationship between glutamine synthetase expression and intramuscular glutamine concentration in the horse

Glutamine plays important roles in the interorgan transport of nitrogen, carbon and energy but little is known about glutamine metabolism in the horse. In this study we determined the tissue distribution of glutamine synthetase expression in three Standardbred mares. Expression of glutamine synthetase was highest in kidney and mammary gland, and relatively high in liver and adipose tissue. Expression was lower in gluteus muscle, thymus, colon and lung, and much lower in small intestine, pancreas and uterus. The pattern of glutamine synthetase expression in the horse is similar to that of other herbivores and it is likely that skeletal muscle, liver, adipose tissue and lungs are the major sites of net glutamine synthesis in this species. Expression did not differ between adipose tissue depots but did vary between different muscles. Expression was highest in gluteus and semimembranous muscles and much lower in diaphragm and heart muscles. The concentration of intramuscular free glutamine was inversely correlated with expression of glutamine synthetase (r=-0.81, p=0.0017). The concentration of free glutamine was much higher in heart muscle (21.6+/-0.9 micromol/g wet wt) than in gluteus muscle (4.19+0.33 micromol/g wet wt), which may indicate novel functions and/or regulatory mechanisms for glutamine in the equine heart.     

The regulation of glutamine transport and glutamine synthetase in Salmonella typhimurium.

Transport of glutamine by the high-affinity transport system is regulated by the nitrogen status of the medium. With high concentrations of ammonia, transport is repressed; whereas with Casamino acids, transport is elevated, showing behaviour similar to glutamine synthetase. A glutamine auxotroph, lacking glutamine synthetase activity, had elevated transport activity even in the presence of high concentrations of ammonia (and glutamine). This suggests that glutamine synthetase is involved in the regulation of the transport system. A mutant with low glutamate synthase activity had low glutamine transport and glutamine synthetase activities, which could not be derepressed. A mutant in the high-affinity glutamine transport system showed normal regulation of glutamate synthase and glutamine synthetase. Possible mechanisms for this regulation are discussed.     

Transport of glutamine and glutamate in kidney mitochondria in relation to glutamine deamidation

1. In the absence of added ADP glutamine is transformed by pig kidney mitochondria to ammonium glutamate, which appears in the external medium. This reaction is stimulated only slightly by the addition of ADP, but under these conditions about 20% of the glutamate is oxidized to aspartate. 2. Externally added glutamate is oxidized to aspartate, and at about the same rate as glutamine. 3. The net rates of glutamine and glutamate influx into the intramitochondrial compartment are very slow. 4. The phosphate-dependent glutaminase activity of intact mitochondria is stimulated by the provision of energy. 5. The provision of energy also decreases the concentration of glutamate and increases the concentration of glutamine in the intramitochondrial compartment. These energy-linked changes in the glutamine and glutamate concentrations are of equal magnitude. 6. It is suggested that transport of glutamine and glutamate across the inner membrane of kidney mitochondria occurs by an obligatory exchange between the two metabolites, and is electrogenic. The existence of an electrogenic glutamine-glutamate anti-porter is proposed.     

Transport of glutamine by Streptococcus bovis and conversion of glutamine to pyroglutamic acid and ammonia

Streptococcus bovis JB1 cells energized with glucose transported glutamine at a rate of 7 nmol/mg of protein per min at a pH of 5.0 to 7.5; sodium had little effect on the transport rate. Because valinomycin-treated cells loaded with K and diluted into Na (pH 6.5) to create an artificial delta psi took up little glutamine, it appeared that transport was driven by phosphate-bond energy rather than proton motive force. The kinetics of glutamine transport by glucose-energized cells were biphasic, and it appeared that facilitated diffusion was also involved, particularly at high glutamine concentrations. Glucose-depleted cultures took up glutamine and produced ammonia, but the rate of transport per unit of glutamine (V/S) by nonenergized cells was at least 1,000-fold less than the V/S by glucose-energized cells. Glutamine was converted to pyroglutamate and ammonia by a pathway that did not involve a glutaminase reaction or glutamate production. No ammonia production from pyroglutamate was detected. S. bovis was unable to take up glutamate, but intracellular glutamate concentrations were as high as 7 mM. Glutamate was produced from ammonia via a glutamate dehydrogenase reaction. Cells contained high concentrations of 2-oxoglutarate and NADPH that inhibited glutamate deamination and favored glutamate formation. Since the carbon skeleton of glutamine was lost as pyroglutamate, glutamate formation occurred at the expense of glucose. Arginine deamination is often used as a taxonomic tool in classifying streptococci, and it had generally been assumed that other amino acids could not be fermented. To our knowledge, this is the first report of glutamine conversion to pyroglutamate and ammonia in streptococci.     

Effect of enteral glutamine on leucine, phenylalanine and glutamine metabolism in hypercortisolemic subjects

The effect of enteral Gln on protein and Gln metabolism was investigated during experimental hypercortisolemia. Four groups of subjects that had received corticosteroids and either enteral Gln (0.5 g x kg(-1) x day(-1) for 2 days) or isonitrogenous Ala-Gly were studied in a fasted or in a fed state. In either state, enteral Gln, compared with Ala-Gly, induced no statistically significant change in the endogenous rate of Leu appearance, an index of proteolysis, Leu oxidation, and nonoxidative Leu disposal, an index of protein synthesis, as studied by kinetics of [1-(13)C]Leu. Similar data were obtained from kinetics of [(2)H(5)]Phe, resulting in an unchanged protein balance in both cases. In contrast, enteral Gln significantly decreased the endogenous rate of Gln appearance and Gln de novo synthesis in the fed state (P < 0.05) as estimated by the kinetics of [(15)N]Gln. This decrease in Gln de novo synthesis induced by Gln could contribute to spare amino acids in hypercatabolic patients.     

Immunochemical characterization of glutamine synthetase from Neurospora crassa glutamine auxotrophs.

Glutamine synthetase derived from two Neurospora crassa glutamine auxotrophs was characterized. Previous genetic studies indicated that the mutations responsible for the glutamine auxotrophy are allelic and map in chromosome V. When measured in crude extracts, both mutant strains had lower glutamine synthetase specific activity than that found in the wild-type strain. The enzyme from both auxotrophs and the wild-type strain was partially purified from cultures grown on glutamine as the sole nitrogen source, and immunochemical studies were performed in crude extracts and purified fractions. Quantitative rocket immunoelectrophoresis indicated that the activity per enzyme molecule is lower in the mutants than in the wild-type strain; immunoelectrophoresis and immunochemical titration of enzyme activity demonstrated structural differences between the enzymes from both auxotrophs. On the other hand, the monomer of glutamine synthetase of both mutants was found to be of a molecular weight similar to that of the wild-type strain. These data indicate that the mutations are located in the structural gene of N. crassa glutamine synthetase.     

Respective effects of glucose and glutamine on the glutamine synthetase activity of human skin fibroblasts

Human A431 carcinoma cell line is known to have 30 fold amplified epidermal growth factor receptor (EGF-R) gene. We have studied the effect of steroid hormone dexamethasone (DEX) and protein synthesis inhibitor cycloheximide (CHX) on the expression of EGF-R gene in this cell line. DEX treatment and protein synthesis inhibition by CHX treatment cause a rapid 3 to 4 fold increase in the level of EGF-R mRNA and combined treatment of the above two agents have less than additive effect. It appears that mRNA for EGF-R accumulate within the cell during protein synthesis inhibition and upon removal of CHX, gets translated into EGF-R specific protein as judged by immuno-dot assay. We did not observe the phenomenon of super induction nor much of an additive effect under condition of combined DEX and CHX treatment.Abbreviations EGF-R Epidermal Growth Factor Receptor - DEX Dexamethasone - CHX Cycloheximide     

Depolarization and synaptosomal glutamine utilization

Synaptosomes prepared by discontinuous Ficoll gradient centrifugation were either pre-incubated with glutamine or incubated with releasing agents in the presence of glutamine. Under both conditions, KCl and 4-aminopyridine (agents with specificity toward the calcium-dependent pool) produced elevated glutamate (but not GABA) release when glutamine was included. AMPA and veratridine produced the same glutamate release in the presence or absence of glutamine. These data support the hypothesis that glutamine utilization is involved in the release of glutamate from calcium-dependent pools.     

Genetic and biochemical characterization of glutamine synthetase from Neurospora crassa glutamine auxotrophs and their revertants.

In this paper we present the isolation and characterization of glutamine auxotrophs of Neurospora crassa and their revertants. The results show that although various enrichment procedures were used, we found only two types of auxotrophs. Genetic crosses performed between the different mutants showed that the mutations responsible for their phenotypes were highly linked and probably affected the same gene. The biochemical characterization of the glutamine synthetase polypeptides of the different mutants showed that both types contained the alpha monomer. However, in place of the normal beta monomer, each type had a new polypeptide differing from normal beta either in its molecular weight or in its isoelectric point. On the other hand, the revertants had only the alpha monomer and were capable of growing without glutamine. On the basis of these data, we propose that the lack of glutamine synthetase activity in the auxotrophs is due to the interaction of the altered beta with the alpha monomer, and as a consequence the alpha monomer of the revertants regains its activity because of the absence of the altered beta.     

Rhythms in glutamine synthetase activity, energy charge, and glutamine in sunflower roots

Roots of sunflower plants (Helianthus annuus L. var. Mammoth Russian) subjected to L12:D12, L18:D6, and L12:D12 followed by continuous light all display rhythms of about 12 hours for glutamine synthetase (GS) activity (transferase reaction) with one peak in the `light phase' and one in the `dark phase.' Root energy charge (EC = ATP+½ADP/ATP+ADP+AMP) is directly correlated with GS, but the GS rhythm is better explained as the result of a rhythmic adenine nucleotide ratio (ATP/ADP+AMP) that regulates enzyme activity through allosteric modification. When L12:D12 plants are subjected to free-running conditions in continuous darkness, only diurnal rhythms for GS and EC, with peaks in the dark phase, remain. The 12-hour root rhythms for GS and EC appear to be composed of two alternating rhythms, one a diurnal, light-dependent, incompletely circadian light phase rhythm and the other a light-independent, circadian dark phase rhythm.

Only glutamine, of the root amino acids, displays cyclical changes in concentration, maintaining under all conditions a 12-hour rhythm that is consistently synchronized with, but nearly always inversely correlated with, GS and EC rhythms.

     

Bacterial whole-cell biosensor for glutamine with applications for quantifying and visualizing glutamine in plants

A whole-cell biosensor for glutamine (GlnLux) was constructed by transforming an Escherichia coli glutamine (Gln) auxotroph with a constitutive lux reporter gene. Measurements of Gln in plant extracts using GlnLux correlated with quantification using high-performance liquid chromatography (Spearman's r = 0.95). GlnLux permitted charge-coupled-device (CCD) imaging of Gln from whole plant organs.